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Mirrors > Home > ILE Home > Th. List > dfbi  Structured version GIF version 
Description: This is our first
definition, which introduces and defines the
biconditional connective ↔. We define a wff of the
form
(φ ↔ ψ) as an abbreviation for
((φ → ψ) ∧ (ψ → φ)).
Unlike most traditional developments, we have chosen not to have a separate symbol such as "Df." to mean "is defined as." Instead, we will later use the biconditional connective for this purpose, as it allows us to use logic to manipulate definitions directly. For an example of such a definition, see df3or 844. This greatly simplifies many proofs since it eliminates the need for a separate mechanism for introducing and eliminating definitions. Of course, we cannot use this mechanism to define the biconditional itself, since it hasn't been introduced yet. Instead, we use a more general form of definition, described as follows. In its most general form, a definition is simply an assertion that introduces a new symbol (or a new combination of existing symbols, as in df3an 845) that is eliminable and does not strengthen the existing language. The latter requirement means that the set of provable statements not containing the new symbol (or new combination) should remain exactly the same after the definition is introduced. Our definition of the biconditional may look unusual compared to most definitions, but it strictly satisfies these requirements. The justification for our definition is that if we mechanically replace (φ ↔ ψ) (the definiendum i.e. the thing being defined) with ((φ → ψ) ∧ (ψ → φ)) (the definiens i.e. the defining expression) in the definition, the definition becomes the previously proved theorem biijust 551. It is impossible to use dfbi 108 to prove any statement expressed in the original language that can't be proved from the original axioms, because if we simply replace each instance of dfbi 108 in the proof with the corresponding biijust 551 instance, we will end up with a proof from the original axioms. Note that from Metamath's point of view, a definition is just another axiom  i.e. an assertion we claim to be true  but from our high level point of view, we are are not strengthening the language. To indicate this fact, we prefix definition labels with "df" instead of "ax". (This prefixing is an informal convention that means nothing to the Metamath proof verifier; it is just for human readability.) dfbi 108 itself is a conjunction of two implications (to avoid using the biconditional in its own definition), but once we have the biconditional, we can prove dfbi2 365 which uses the biconditional instead. Other definitions of the biconditional, such as dfbi3dc 1223, only hold for decidable propositions, not all propositions. (Contributed by NM, 5Aug1993.) (Revised by Jim Kingdon, 24Nov2017.) 
Ref  Expression 

dfbi  ⊢ (((φ ↔ ψ) → ((φ → ψ) ∧ (ψ → φ))) ∧ (((φ → ψ) ∧ (ψ → φ)) → (φ ↔ ψ))) 
Step  Hyp  Ref  Expression 

1  wph  . . . 4 wff φ  
2  wps  . . . 4 wff ψ  
3  1, 2  wb 96  . . 3 wff (φ ↔ ψ) 
4  1, 2  wi 4  . . . 4 wff (φ → ψ) 
5  2, 1  wi 4  . . . 4 wff (ψ → φ) 
6  4, 5  wa 95  . . 3 wff ((φ → ψ) ∧ (ψ → φ)) 
7  3, 6  wi 4  . 2 wff ((φ ↔ ψ) → ((φ → ψ) ∧ (ψ → φ))) 
8  6, 3  wi 4  . 2 wff (((φ → ψ) ∧ (ψ → φ)) → (φ ↔ ψ)) 
9  7, 8  wa 95  1 wff (((φ ↔ ψ) → ((φ → ψ) ∧ (ψ → φ))) ∧ (((φ → ψ) ∧ (ψ → φ)) → (φ ↔ ψ))) 
Colors of variables: wff set class 
This definition is referenced by: bi1 109 bi3 110 bi2 119 dfbi2 365 sb4bor 1626 
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